Simulation of Long-Period Fiber Gratings formed with Helical Fiber

Tools Used: BeamPROP, MOST

Schematic diagram of a helical fiber | Synopsys

Figure 1: Schematic diagram of a helical fiber.

Long-period gratings are widely used as sensors in a variety of fields such as automotive, aerospace, and medicine. Traditional fiber gratings are formed by UV light exposure through a sophisticated phase mask. It has recently been found that a helically twisted fiber can create a similar effect as long-period gratings, and can therefore be used as sensors. Light in a helically twisted single-mode fiber will couple into multiple interfering cladding modes. The pitch or grating period of the helix will determine how this coupling happens, and therefore how the device will operate spectrally. Much like other grating devices, helical fibers are phase-sensitive and require the engineer to carefully design the device to fit the desired characteristics. RSoft’s BeamPROP™ simulation tool is ideal for this application as it couples an efficient algorithm suitable for large devices with a robust design tool that allows for arbitrary index profiles.

A helical shape corresponding to the single- mode fiber described in Ref [1] and Ref [2] can be easily created in the RSoft CAD Environment™ and is illustrated in Fig. 1. A full 3D simulation of the structure was performed using BeamPROP and the results are shown in Fig. 2. Here, we show the power in various modes along the structure as well as the total power in the fiber. Please note that the monitored power of LP1m modes has been scaled by 2 times due to the rotation symmetry of these modes. BeamPROP software makes it easy and convenient for the user to make measurements of the field propagating in the device.

Power coupling between LP01 and cladding modes. These results account for mode degeneracy | Synopsys

Figure 2: Power coupling between LP01 and cladding modes. These results account for mode degeneracy.

BeamPROP’s software package includes MOST™, a utility which automates parametric studies. This utility can be used to study device characteristics as a function of any design parameter. The inset in Fig. 2 illustrates how the grating pitch affects the coupling length. From this, the designer can determine appropriate design parameters and tolerances of a particular device.

Cross-sectional field profiles at different propagation distances | Synopsys

Figure 3: Cross-sectional field profiles at different propagation distances. 
Left: Transverse Field Profile at Z=2mm Right: Transverse Field Profile at Z=14mm

A rigorous tool like BeamPROP provides us with more information than a simple analytical model, which might only account for coupling between the fundamental LP01 and the next higher LP11 mode. BeamPROP, which is based on the Beam Propagation Method (BPM), directly simulates the field propagating in the structure. Therefore, all propagating higher order cladding modes are included. Any power not accounted for in the fundamental LP01 and the next LP11, LP02, and LP12 modes shown resides in even higher order modes. Representative field profiles along the helix shown in Fig. 3 also illustrate the highly multimode nature of this device.

 Spectral response of a helical fiber with a pitch of Λ=0.647mm and grating length L=14mm | Synopsys

Figure 4: Spectral response of a helical fiber with a pitch of Λ=0.647mm and grating length L=14mm.

For a fixed pitch of Λ=0.647mm and a grating length L=14mm, we obtain the spectral response shown in Fig. 4 through a parameter scan over the wavelength using MOST.

Once again, BeamPROP provides a robust approach to study the cladding mode coupling in long-period helical fiber gratings, and gives the engineer a key tool in specifying the design and manufacturing tolerances for this long period grating.

References:

[1] G. Shvets, et al, "Polarization properties of chiral fiber gratings," Journal of Optics, Vol. 11, No. 7, May, 2009. 
[2] J. Qian, et al, "Coupled-Mode Analysis for Chiral Fiber Long-Period Gratings Using Local Mode Approach," IEEE J. of Quantum Electronics, Vol. 47, No. 11, Nov. 2011.